WO1990001679A1 - Navigation system - Google Patents

Abstract

Route searching (35) to the destination is performed by use of a road data (26) having each crossing data and road data and by inputting the destination to generate navigation data (27) and a course to the destination is directed while the present position is being traced (37). A course guide to the end crossing of the present position road is output by use of data on travelling guide from each crossing to the destination obtained via route searching (35) from the road network data (26). At a crossing, the present position is traced on a travelling direction road which has been recognized by a present position trace means (37) and the end crossing of that road is recognized. Recognition of a travelling direction is made at the end crossing of a road between crossings and the road in the travelling direction is used as the present position road to output a guide to the next end crossing and this procedure is repeated at each crossing up to the destination and course guiding is thus performed. In route searching, a travelling road to the destination is set for each crossing. Therefore, course guiding to the destination from the end crossing of a travelling road can be conducted by recognizing a crossing and its travelling road.

Description

 Detailed navigation device

 Technical field

 The present invention relates to a navigation device that searches for a route to a destination by inputting the destination, and provides a course guidance to the destination while tracking the current position. The present invention relates to a navigation device having a current position calculating function of detecting a current position and calculating a current position for each intersection based on an angle comparison with road network data.

 Background technology Navigation devices are used to provide course guidance to drivers who are unfamiliar with geography, and in recent years, these navigation devices have been actively developed. .

 A conventional navigation device sets a course from a departure point to a destination by inputting a departure point and a destination before traveling, and performs navigation according to the set course. is there. In the navigation, when indicating a course, a map is displayed on the CRT screen and the course is superimposed on the map, and at some intersections, the intersection to be turned next according to a preset course As information, the distance to the next intersection to be turned is displayed as a number graph, a special photo, or a combination of voice output.

However, conventional navigation devices are In this way, a course from the departure point to the destination is set, and course guidance is provided according to the set course. For this reason, for example, if an incorrect decision is made at an intersection or the like and the car deviates from the course, return to the course that has been set again, or follow the guidance of the navigation device if the course is not set again using that position as the starting point. There is a P problem that you can not continue running. However, returning to the set course and setting the course from that position as a departure place place a very heavy burden on the driver. In other words, the need for course guidance means that you are not familiar with the road conditions in the area.If you are lost in such an unknown area, if you are still at the place of departure or destination, where is your current position It is difficult to recognize even

In addition, whether or not the vehicle has passed a predetermined intersection as instructed by the course is based on the assumption that the travel distance, right turn, left turn, etc. will be detected by a distance sensor or steering angle sensor. There is also a problem that there is a detection error, and the detection error is accumulated to induce a judgment error. In the conventional navigation device described above, the course from the departure point to the destination is set, and the travel distance is integrated while detecting right and left turns etc. according to the course, so that the distance error is also integrated. The correction is lost. Furthermore, on a branch road where only the current position on the course can be specified and the angle difference is small, if the angle is within the allowable error, it is determined that the vehicle has proceeded correctly with that much information, so a determination error Is also likely to occur There is also a problem.

 An object of the present invention is to ensure that the current position can be calculated for each intersection at any point without fixing the course. Another object of the present invention is to enable appropriate guidance information to be output at any point. Still another object of the present invention is to be able to recognize a current position at an intersection and correct a distance error.

DISCLOSURE OF THE INVENTION For this purpose, the present invention provides a navigation device that searches for a route to a destination by inputting the destination, and provides a course guide to the destination while tracking the current position. Road network data having road information between intersections, road recognizing means for recognizing a traveling direction road at an intersection, and a current position for recognizing an end point intersection of the road by tracking a current position on the road recognized by the road recognizing means. It is provided with recognition means, and performs intersection recognition processing based on road network data on the condition that the vehicle has entered a predetermined range from the end intersection (/ recognizes the traveling road). By recognizing the traveling direction at the end intersection of the road between the intersections and outputting the guidance of the next end intersection with the road in the traveling direction as the current position road, the destination is obtained. For this reason, the course guidance is repeated for each intersection at each intersection.Therefore, as the road network data, at least intersection data having information on the road and position of the end point and the start point for each intersection, and the start point intersection, the end point intersection, and Road data with information on single-row pointers, locations of nodes composing the road Equipped with node string data with information, the course guidance is provided by setting the direction of travel to the destination at each intersection by inputting the destination.

 Also, road network data having road network information based on the intersection, steering angle detecting means, distance detecting means, calculating means for calculating the vehicle direction and trajectory from the steering angle and the traveling distance, and Bending point detecting means that detects a bending point and calculates its position, calculates the vehicle bending angle from the bending point position, calculates the bending angle of the connecting road at the intersection from the road network data, and selects the traveling road The method is characterized by calculating the angle from the bending point position and the three points on both sides thereof, and calculating the current position from the approach road and intersection information.

 According to the present invention, the inflection point is detected by the inflection point detecting means, the position thereof is calculated, and the vehicle selecting angle and the bending angle of the connecting road are calculated by the road selecting means to select the traveling road. The current position can be easily calculated. In addition, since the current position is calculated based on the inflection point, the distance can be easily corrected from the inflection point, and the error in the data at each intersection can be absorbed. In addition, by detecting angles from the three points of the bending start point, bending end point, and bending point corresponding to the running state at the time of bending, there is no effect even if the vehicle makes a large turn or a small turn at the same intersection Angle detection can be performed.

Furthermore, based on the road network data, intersection recognition processing is performed on the condition that the vehicle has entered a predetermined range from the end intersection, and By recognizing the road in the line direction and outputting the guidance of the next intersection at the intersection with the road in the traveling direction as the current position road, guidance information to the destination from any intersection can be obtained. Therefore, even if a road different from the guided course is selected as the direction of travel, guidance on the direction of travel to the destination at the end intersection of the road can be output, so that the optimal course may not be followed due to road congestion, etc. Even if you pass the difference point, guidance to the destination can be obtained.

 BRIEF DESCRIPTION OF THE FIGURES

 FIG. 1 is a diagram showing a system configuration for explaining a current position calculation 1 embodiment of a navigation device according to the present invention, FIG. 2 is a diagram for explaining selection of a traveling road,

 FIG. 3 is a diagram for explaining the calculation process of the vehicle direction and the trajectory,

 FIG. 4 is a diagram illustrating an example of a processing routine for detecting a bending point, FIG. 5 is a diagram illustrating an example of a processing routine for calculating a bending position, FIG. 6 is a diagram illustrating an example of a processing routine for selecting a road, FIG. 7 is a diagram showing an example of a processing routine for calculating a vehicle bending angle, FIG. 8 is a diagram showing a steering angle, a bending start point, a bending point position, and a bending end point;

 Fig. 9 is a diagram showing an example of the routine for reading roads coming out of an intersection.

 FIG. 10 is a diagram showing an example of a processing routine for calculating a connecting road bending angle,

Fig. 11 is a diagram for explaining how to determine the bending angle of the connecting road, FIG. 12 is a diagram showing an example of a processing routine for distance error correction, FIG. 13 is a diagram for explaining the processing content of distance error correction, and FIG. 14 has a current position calculating function according to the present invention. FIG. 1 is a diagram showing a system configuration of a navigation device according to an embodiment;

 FIG. 15 is a diagram for explaining the overall processing flow, and FIG. 16 is a diagram showing an example of a data structure of a road network and intersection data, road data and node train data,

 FIG. 17 is a diagram showing an example of a destination input menu screen, FIG. 18 is a diagram for explaining an example of route search output, FIG. 19 is a diagram showing an example of guidance output,

 FIG. 20 is a diagram showing a processing routine of a current position input, FIG. 21 is a diagram showing an example of a processing routine of current position tracking, FIG. 22 is a diagram showing an example of a processing routine of initial position setting, FIG. 23 shows an example of a sensor detection processing routine, FIG. 24 shows an example of a remaining distance calculation processing routine, and FIG. 25 shows a modification of the current position tracking processing routine. ,

 FIG. 2S is a diagram for explaining inflection point detection,

 Fig. 7 is a diagram for explaining the intersection approach direction and bending angle comparison process.

 FIG. 28 is a diagram showing an example of a processing routine corresponding to the process of FIG. 27.

 Fig. 29 is a diagram showing an example of a processing routine for reading roads entering an intersection.

FIG. 30 is a diagram for explaining the current position correction process, FIG. 31 is a diagram showing an example of a processing routine corresponding to the process of FIG. 30;

 FIG. 32 is a diagram showing a modified example of the nipping device according to the present invention,

 Figure 33 shows an example of route order,

 Fig. 34 is a diagram for explaining the flow of the navigation process,

 FIG. 35 is a diagram for explaining the route search processing.

 BEST MODE FOR CARRYING OUT THE INVENTION

In FIG. 1, a distance sensor 1 detects a traveling distance of a vehicle, a steering angle sensor 2 detects a steering angle of an operated vehicle, and a sensor reading unit 3 reads these detection signals. The processing is performed. The vehicle azimuth trajectory calculation unit 4 calculates the vehicle azimuth and the trajectory from the steering angle every time the vehicle travels for a certain distance. The road network data 5 is composed of information on intersections, roads connecting the intersections, node trains constituting the roads, and the like. The navigation data 6 includes course guidance information, set course information, and other data necessary for navigation. The inflection point detection unit 7 performs an intersection recognition process, has a inflection point position calculation unit 8 under its control, detects the inflection start point and the inflection end point within the error range of the intersection, and detects the intersection position. Calculate the corresponding inflection point position. The road selection unit 9 has a vehicle and a bend angle calculation unit 1◦, a road reading unit 11 from the intersection, and a connecting road bend angle calculation unit 12 under its control. Regardless of whether or not the vehicle is selected, the actual vehicle turning angle is compared with the connecting road bending angle obtained from the road network data to select the road that has passed the intersection. Then, the distance error correction unit 13 corrects the distance error based on the detected bending point position and the selected traveling road, and obtains the current position on the traveling road. That is, here, the remaining distance to the end point intersection on the current position road is obtained. With the above-described configuration, the present invention provides, for example, as shown in FIG. 2 (a), when a vehicle takes a course of turning right at an intersection, the bending angle is determined when bending is completed. As well as all outgoing roads for the road entering the intersection as shown in Fig.

(Connected roads) Calculate the bending angles I, ₂ ^ 3 for ①, ②, ③. Then, by comparing these angles, the nearest traveling road that falls within the allowable error is selected. Next, an example of a specific process of each unit will be described.

 As shown in FIG. 3, the vehicle azimuth trajectory calculation unit 4 samples the mileage and the steering angle Sta every time the vehicle travels a fixed distance d, and obtains a new azimuth and trajectory (X, Y) from the previous vehicle azimuth An The vehicle direction and trajectory are calculated and stored in the memory. For example, the vehicle direction A ng (i) is calculated from the steering angle S t a (ί) read from the sensor at regular intervals and the vehicle rotation angle (9 (s t) with respect to the previously stored steering angle.

 An g (i) = θ (Sta (i)) + An g (i-1)

 In addition, the vehicle trajectory (X (i), Y (i)) is

(X (i), Y (i)) = (X (i-1) + dx, Y (il) + dy)

 d x = d x cos (7Γ— An g (i))

 d y = d Xsin (7r— An g (i))

Can be obtained by using the following equation.

 Inflection point detection 7

 (S 1) First, it is determined whether the “bending end waiting flag” and the “bending detection flag” are off and the steering angle is larger than the threshold value. Set the “Bend start point” to the current distance (“Previous distance sensor value” + i) and set the “Bend detection flag” to ON. In other words, the steering angle becomes larger than the threshold value for the first time, so that the bending detection process is started. However, in the case of NO (during bending detection, or during so-called assumed straight running where the steering angle is below the threshold value),

(S 2) Subsequently, it is determined whether the “bending detection flag” is on and the steering angle is smaller than the threshold value, and if YES (bending was detected last time and the vehicle has turned this time), the rotation angle is set to the current rotation angle. Set to the difference between the azimuth and the azimuth at the bending start point. Then, it is checked whether the rotation angle is greater than 2 °. If the rotation angle is less than 20 ”, it is not possible to judge that the intersection has been turned, so the“ bending detection flag ”is turned off. However, if the rotation angle is greater than 20 °, it can be determined that the vehicle has turned at the intersection. Here, the “bending point detection flag” is turned off, and the “bending end waiting flag” is turned on, and the “bending end waiting position” is set to the current position. Set to distance. This is used to calculate the inflection point position. Also, N〇 (end of bending, still detecting bending, or Is running straight)

 (S3) Further, it is determined whether the "bending point end waiting flag" is on and whether ("bending point end waiting position" + 1 Om) is smaller than the current distance, and YES (from the end of bending) In this case, set the rotation angle to the difference between the current azimuth and the azimuth at the bending start point. Then, it is checked whether the rotation angle is greater than 20 °, and if the rotation angle is less than 20 °, the “bending point ^ end waiting flag” is turned off, but if the rotation angle is greater than 20 °, “ Turn on the bend point detection flag, turn off the bend end wait flag, set the bend end point to the current distance, and calculate the bend point position.

In the above processing, the bending point position calculator 8 calculates the bending point position. Here, as shown in Fig. 5, the intermediate distance B between the bending start point A and the bending I end point C. And the intermediate direction d of the vehicle direction Ang, the loop counter j is 1, and B is the average distance B. And the vehicle direction Ang (B) at distance B and the vehicle direction Ang (B) when Bo soil j is set to B while incrementing the loop force counter j. Search for a point that matches azimuth d, and set matching point B to the inflection point position. The distance D _UP from the bending start point A to the bending point position B, and the distance D _d from the bending point position B to the bending end point C. _{Find wn} . Fig. 8 shows these relationships.c In addition, as shown in Fig. 8 (a), the bending start point A and the bending end point C become the bending start point when the steering angle exceeds the threshold value. A is set, and when the steering angle returns to within the threshold value, that point is And a point at which the vehicle travels 1 Om from that point is set as the bending end point C.

 The road selector 9 first calculates the bending angle of the vehicle as shown in FIG. Then, the road exiting from the intersection is read and the bending angle of each connecting road is calculated, and the difference between the connecting road bending angle and the vehicle bending angle is determined to be the minimum value. If the minimum value is less than 40 °, the road bank is set to “Road No. of the current location road”. If the minimum value is 40 ° or more, the corresponding road is set. Is determined not to be detected, and the “current position tracking failure flag” is turned on. In other words, the road closest to the bending angle of the vehicle is selected as the traveling road for all connected roads, but if the error between them is large, the current position cannot be calculated and the current position is reset. I have to.

The vehicle bending angle calculation unit 10 checks whether the "bending point detection flag" is off as shown in Fig. 7, and if it is on, the bending end point, bending point position, and bending start point It is obtained in the bending point detection process (Fig. 4), but if it is off, these values are not obtained, so the following values are set. In other words, the current distance (“previous distance sensor value” + i) is calculated as the end point of bending, the value obtained by subtracting the intersection error range distance from the current distance is calculated as the bending point position, and the current distance is calculated as the bending start point. Double the intersection error range distance from the difference. Then, ABC shown in Fig. 8 is obtained as the vehicle bending angle from the coordinates of these three points. When the vehicle bending angle calculation is completed, the road reading unit 11 that exits from the next intersection operates. In this process, first, as shown in FIG. The data is read from the data, and the road ban is set to the “road judge” and “first road ban”, respectively. Then, set 0 to the loop force counter j. Next, while incrementing the loop force counter j, the next road ban signal having the same starting point is sequentially read from the road data until it becomes the “first road acknowledgment”, and all road acknowledgments are read out. Read it out and set the number to “number of roads to go out”.

As shown in Fig. 10, the connecting road bending angle calculation unit 12, which calculates the connecting road bending angle in selecting a road (Fig. 6), firstly stores the node row of the road identification of the current position road in the road data. Data from the node sequence data and calculate the coordinates (x _A , y _A ) of point A at a distance D _UP from the ^ point. Then, the end point B of the node example is set as coordinates (χ _Α , y A). Next, the node train of the road coming out of the intersection is read from the road data and the node train data, and the distance D _d from the starting point is read. C coordinate points _wn (x _A, y _A) is calculated. Further, from these coordinates, points A ′ and C ′ on the circles AB and BC that are inscribed with these straight lines are defined as arcs (Α ′ C ′) having a length of D _UP + D _d . Assuming an inscribed circle to be _wn , calculate the coordinates of points A 'and C, and find the intersection of the inscribed circle and a straight line bisecting ABC as point B'. A '''C obtained as a result is set to "connection road bending angle". Figure 11 shows these relationships. Ah

As shown in Fig. 12, the distance error correction 13 first, as in the case of the initial position setting, follows the "road number of the current position road", and converts the road length, the end intersection, and the node column into road data, The data is read from the node sequence data, and these are set in the “current position road length”, “current position road end intersection”, and “current position road node sequence”. Then, it is checked whether the “bending point detection flag” is on or not, and a difference D between the current distance (“previous distance sensor value” + i) and the bending point position is obtained. Subtract from "length" and set the result to "remaining distance to intersection". In other words, here, a process is performed to correct the error up to that point by adding a new road to the length of the new road by entering the next road after turning at the intersection. However, when the "Bend point detection flag" is off, the value obtained by adding "Remaining distance to intersection" to "Length of current road" is updated as new "Remaining distance to intersection" I do. This is a process corresponding to the case where the vehicle passes through an intersection without making a turn. For example, if the “remaining distance to the intersection” is 0 at that intersection, the “current road length” is added as it is. It will be set as the “remaining distance to the intersection”. FIG. 13 shows the results of error correction when a bending point is detected and when it is not detected. If the difference between the distance between the inflection point position and the intersection position is ed as shown in Fig. 5), then the inflection point position is taken as the intersection position and the remaining distance to the next intersection is calculated as shown in Fig. 4 (b). D is corrected. Next, an example of a system configuration of a navigation device having a current position calculation function will be described.

 In FIG. 14, an input unit 21 is constituted by input means using hard keys, touch input means from a display screen, and the like, and is used for destination input, current position input, start input, and the like. The output unit 25 includes a display, a sound output device, and the like, and displays a menu necessary for performing a destination input or a current position input, and outputs course guidance information. The navigation data 27 includes course guidance information, set course information, and other data necessary for navigation, and stores the navigation data generated by the navigation processing unit 24. The flag table 28 is a table for registering a flag necessary for performing navigation, and is accessed from the navigation processing unit 24 according to the processing status, and is updated as appropriate. The navigation processing unit 24 is constituted by, for example, a computer, accesses the road network data 26, the navigation data 27, and the flag table 28, and inputs data and information input from the input unit 21 to the distance sensor 2. 2. Processes the detection signal of the steering angle sensor 23.

The navigation processing unit 24 includes an input data processing module 31 for analyzing and processing data and information input from the input unit 21; a distance data processing module 32 for processing a detection signal of the distance sensor 22; and a steering angle. It has a steering angle data processing module 33 that processes the detection signal of the sensor 23, Based on the data and information input from the processing unit, the _c processing control module ₃₄ having a plurality of processing modules for performing the processing necessary for the navigation is performed according to the instruction information input from the input unit 21. The navigation processing unit 24 controls the entire processing. The flag search unit 28 refers to the flag table 28 as needed, and the route search module 35, the current position input module 36, and the current position tracking module 3 Control 7

 When a destination is input from the input unit 21, the route search module 35 searches for an optimal route to guide the user to the destination while accessing the road network data 26. The optimal traveling direction to the destination is set at all intersections of the target road network data 26. Then, the searched data is stored in the navigation data 27. In this case, focusing on a certain intersection, a road is selected according to the traveling direction set at the intersection, the vehicle is driven, and the road is selected at the next intersection and further at the next intersection according to the repeatedly set traveling direction. Is set so that the vehicle can reach the destination on the optimal route by traveling. Here, the meaning of not the shortest but the optimal one means that in the route search, considering the width of the road, the number of passing intersections, the traffic volume and other driving conditions, etc. It is not necessary, but the search will be as short as possible when converted by the travel time.

When the current position is input from the input unit 21, the current position input module 36 receives the road network data 26 and the navigation data. Recognizes the current position from data 27 and draws the corresponding intersection shape, direction, landmark, intersection name, direction of travel road, etc., displays it on the screen of the output unit 25, and sets the data necessary for navigation Is what you do. Then, set the necessary flags so that the tracking of the current position is activated by the start input ^.

 The current position tracking module 37 is activated when a route search is performed, navigation data is set, and the current position is input, and signals from the distance sensor 22 and the steering angle sensor 23 and the navigation data 27 and The intersection is detected based on the road data 26, and the current position is tracked while repeating the current position recognition processing for each intersection. The state at that time is appropriately set in the flag table 28 as a flag, and the transition to each processing step is determined by referring to this flag. Therefore, it has sub-modules such as initial position setting 38, sensor detection 3-9, remaining distance calculation 40, bending point detection 41, road selection 42, and distance error correction 43.

The remaining distance calculation 40 always calculates the remaining distance to the intersection in order to detect the current position from the intersection, and performs the intersection recognition processing when the remaining distance to the intersection reaches a predetermined value. is there. The inflection point detection 41 performs an intersection recognition process, and detects an inflection start point and an inflection end point within an error range of the intersection to detect an inflection point position corresponding to the intersection position. Road selection 42 is selected by actually passing through the intersection, regardless of whether or not the guided direction road was selected. The detected road is used, and based on the result, guidance of the traveling direction at the end intersection of the road is provided. Then, the distance error correction 43 corrects the distance error based on the detected bending point position and the selected traveling road, and obtains the current position on the traveling road. That is, here, the remaining distance to the end intersection on the current position road is obtained.

 In this way, by detecting the current position at the intersection and recognizing the road on which it travels, even if guidance is provided for the intersection at the end of the road, even if it does not proceed as guided at the intersection, Guidance based on the selected road can be provided, and navigation is continued. In other words, guidance in the direction of travel at each intersection is merely guidance, and it is possible to continue the Napierge without having to use that road as the direction of travel.

 Processing by the navigation device having the current position calculation function will be described. First, prior to the description of the processing, an example of a data structure provided in the navigation device having the current position calculation method according to the present invention will be described.

 Now, for example, if there is a road network consisting of intersections No.I-W and Road Nos. I-II as shown in Fig. 16 (a), the intersection data is shown in Fig. 16 (b) and the road data is The node data has the data structure as shown in FIG.

The intersection data corresponds to the intersection numbers I to as shown in FIG. Among the roads where the intersection is a melting point, information on the road where the intersection is a melting point, information on the location of the intersection (east longitude, north latitude), and the name of the intersection are included.

 Also, as shown in Fig. 3 (c), the road data includes the next road signal among the roads with at least the same starting point and the next road among the roads with the same ending point corresponding to road signals ① to ⑭. Bango, intersection Information about the starting point, points, node train pointers, and road lengths of the Bango. As is evident from the figure, for the roads with the same starting point, the next road signal, and for the roads with the same ending point, the next road ban, search for the same ban from the starting point and ending point of the intersection. Can be generated by The road length can also be obtained by integrating the position information of the following node sequence data.

 As shown in Fig. 4 (d), the node sequence data has the number of nodes at the head where the node sequence pointer in the road data points, and then the node positions (East, North latitude) Has information. In other words, a node sequence is configured for each road data. The example shown in the figure shows a node sequence of road identification numbers I and II.

As is clear from the above data structure, the unit of the road ban is composed of multiple nodes. In other words, node train data is a set of data related to one point on the road, and what connects nodes is called an arc.By connecting each of a plurality of node trains with an arc, A road is represented. For example, if you look at the road bank No. ①, the node sequence of road data It is possible to access the node sequence data A0000 from the pointer, and here, the road council 力 is composed of 15 nodes.

 Also, for example, if attention is paid to intersection signal V, in the course starting from this point, first, information on the road where the intersection data appears will be used to determine the road ban No.⑦ From the information of "next road sign having start point", road sign ⑫ is searched. Then, from the same information on the road ban No. 道路, the Road No. ⑭ and then ⑦ are searched. Here, since the Road No. で あ is the first road number, it can be determined that there is no other road ban No. as the surrounding road. This is the same for the end point. By using intersection data and road data in this way, it is possible to search for roads that enter and exit at each intersection, and to determine the distance of the route connecting each intersection. Furthermore, by adding driving conditions such as prohibition of entry and prohibition of right and left turns and road width to these data, it is possible to provide, for example, information for performing a route search described later in detail. .

 Next, the overall processing flow will be described with reference to FIG.

 (S 1) First, enter the destination. In the destination input, for example, a menu screen as shown in FIG. 17 is displayed, and the destination code (“00001”) is touch-input with the numeric part as a numeric keypad.

(S2) Next, the mode is changed to the route search mode, and the destination is set for each intersection. The optimal route direction up to is set. For example, in the road network shown in Fig. 16 (a), assuming that intersection I is the destination, as shown in Fig. 18 (a), each of intersections Π to W has a traveling direction to the destination. Is set. Figure (b) shows an example of the data. In this route search, the traveling direction of each intersection is set by sequentially obtaining, for example, the direction of the shortest distance to the destination from the intersection close to the destination.

 (S 3) Enter the current position as the departure place. Although detailed description will be given later with reference to FIG. 20, in this processing, the “current position tracking failure flag”, the “destination guidance flag”, etc. are turned off.

 (S4) When the input processing of the current position is performed, the guidance of the traveling direction at that position becomes possible, and the current position is tracked by processing the signals of the distance sensor and the steering angle sensor according to the traveling. A detailed description will be given later with reference to FIG. 21.In this process, first, the "intersection arrival flag" is turned off at the initial stage, and information such as the length of the current road, the end intersection, the node train, etc. Recognizes the current location, tracks the current location, and determines whether or not the vehicle has arrived at the guided intersection.When the vehicle arrives at the guided intersection, it turns on the "intersection arrival flag" and cannot detect the guided intersection. Turn on the "current position tracking failure flag".

 (S5) After the tracking processing of the current position, it is checked whether the "intersection arrival flag" is ON or OFF.

(S 6) Then, when the “intersection arrival flag” is off, further check whether the “current position tracking failure flag” is on or off, If the “current position tracking failure flag” is off, it can be determined that the course is not out of course, so the process returns to step S4 and continues to track the current position again. However, if the “current position tracking failure flag” is on, it is determined that the course has deviated, and the process returns to step S3 to input the current position as the departure place again. C (S7) “Intersection arrival flag” If is turned on, then it is checked whether the "destination guidance flag" is turned on. The "destination guidance flag" is turned on when the end point intersection of the current position road becomes the destination intersection in processing step S10 described later. If the "destination guidance flag" is on, it means that the guidance to the destination intersection has been completed, and the process returns to the initial destination input processing.

 (S 8) However, if the “destination guidance flag” is still off, the destination intersection will be further ahead of the next intersection, so the progress of the ^ intersection of the current position road By reading the direction data, drawing the intersection shape, intersection characteristics, landmarks, direction of travel at the intersection, etc. on the screen as shown in Fig. 19, and displaying the intersection name and the remaining distance to the intersection, Output guidance. At this time, the "intersection arrival flag" is also turned off.

 (S 9) Then, it is checked whether or not the end intersection of the current position road is the destination intersection. If it is not the destination intersection, the process returns to the current position tracking in step S4.

(S10) If the end intersection of the current position road is the destination intersection, turn on the "Destination guidance flag" and go to step S Follow the current position tracking of 4.

 The above is the overall processing flow.

 Next, the main processing routine of the above steps will be described in more detail.

 In the processing routine of the current position input S3, first, when an intersection signal is input, the intersection direction, the intersection shape, the intersection name, the intersection mark, etc. are obtained from the intersection data, road data, and node row data described above. Then, the intersection name, intersection characteristics, and traveling direction are drawn and displayed on the screen as shown in FIG. 20 (a) (S31, S32). Then, the traveling direction data at the intersection Ban, which was input based on the traveling direction data shown in Fig. 18 (b) as the road ban of the current position road, is stored, and the traveling direction road is shown in Fig. 20. ) And draw with arrows (S33, S34). After that, wait until there is a start input, and when the driver makes a start input when passing through an intersection, the "current position tracking processing flag" is turned on, and the "current position tracking failure flag", "destination guidance flag", The "intersection arrival flag" is turned off respectively (S35, S36).

As shown in FIG. 21 (S11), the processing routine of the current position tracking first checks whether the "current position tracking initialization flag" is turned on. If only the current position is input and the initial data for tracking the current position is not set, it is on, so the initial position is set as shown in Fig. 22. When this setting is made, the “current position tracking initialization flag” is turned off. Migrate directly.

 In the initial position setting, as shown in Fig. 22, the road length, end intersection, and node column are read from the road data and node column data according to the "road number of the current position road", and these are read as " Set in "Length", "End point intersection of current location road", "Node row of current location road". In addition, it reads the signal of the distance sensor and sets the value to the “current distance sensor value”. Then, the "current position tracking initialization flag", "error range flag", "error range passing flag", "bending end waiting flag", "bending point detection flag", "bending detection flag" and the like are turned off. And set “Length of current road” to “Remaining distance to intersection”.

 (S 4 1 2) Next (The sensor detection process shown in Fig. 23 is performed. In this process, first, the current sensor value is set as the previous sensor value for the distance and the steering angle, and then the sensor is detected. The value is read and used as the current sensor value, and the amount of change in the steering angle corresponding to the distance traveled is found, and the steering angle S ta at the current position is found.

(S 4 13) After setting the loop force counter i to 0, repeat the processing from the calculation of the remaining distance until the loop force counter i reaches the advanced distance while incrementing the loop counter i. In the remaining distance calculation, as shown in Fig. 24, the remaining distance to the intersection is sequentially subtracted and updated to determine whether or not the vehicle has entered the intersection error range distance. Until within the intersection error range distance, turn off the "error range flag" And repeat the calculation of the remaining distance. When the remaining distance to the intersection falls within the intersection error range distance, the "error range flag" is turned on. Then, if the vehicle goes out of the intersection error range after turning on the "error range flag", the "error range passing flag" is turned on.

 (S4 14) When the “error flag” is turned on, the vehicle direction and trajectory are calculated to detect the bending point.

 (S4 15) Check whether the “Bending point detection flag” is ON, and if OFF, increment power counter i and repeat the same process. Make a selection. Also, once within the intersection error range distance, the "error range flag" was turned on, but the inflection point was not detected and the "flexion point detection flag" was off and the vehicle went out of the intersection error range distance. As described above, the “error range flag” is turned off and the “error range passing flag” is turned on, as described above in S 4 13. This includes the case where the vehicle passes through an intersection without making a turn. In this case, the next road is selected in the same manner.

 (S4 16) Check whether the “current position tracking failure flag” is ON, and if it is ON, return to S3 from steps S5 and S6 in Fig. 15 and turn OFF. If it remains, correct the distance error continuously.

(S4 17) Turn on the “intersection arrival flag”, increment the loop force counter i, and repeat the same process. As described above, in the navigation device having the current position calculation method according to the present invention, various flags are used to process information. The main items are as follows.

 "Intersection arrival flag": In the case of ON, guidance output for the next intersection is performed. It is turned off when inputting the current position and turned on when passing through the intersection.

 "Destination guidance flag": If it is on when arriving at an intersection, it is determined that the vehicle has arrived at the destination, and the main routine is returned to the beginning (destination input processing). If the next intersection is the destination at the time of guidance output, turn it on.

 “Current position tracking failure flag”; in the case of ON, the current position tracking process returns, and the main routine branches to input the current position again. When selecting a road, turn it on if there is no road to select.

 “Current position tracking initialization flag”: In the case of “on”, it calls the initial position setting routine. It is turned off when the initial position is set and turned on when the current position is input.

 "Error range flag": In the case of ON, the calculation of the trajectory, the detection of the inflection point, etc. are performed. If it is within the error range of the intersection, it is turned ON, otherwise it is turned OFF.

 "Error range passing flag": In the case of ON, the road is selected. If it passes the intersection error range, it is turned ON, otherwise it is turned OFF.

"Bending point detection flag"; In the case of a talent, the current position tracking In addition to selecting the road, the current position is reset by correcting the distance error, and if off, the bending start point, bending end point, and bending point position are set by calculating the vehicle bending angle. Turns off when the position is set, turns on when a bending point is detected, and turns off after correcting the distance error.

 "Bending detection flag" and "Bending end waiting flag": Performs bending detection and bending end point detection, and is turned off by setting the initial position. Then, the “bending detection flag” is turned on when the steering angle exceeds the threshold value, and the on / off state is controlled depending on whether or not the rotation angle exceeds 20 °.

 Next, a modified example of the navigation device having the above-described current position calculation method will be described.

 In the above embodiment, the current position is tracked based on the road ban and the remaining distance from the end intersection of the road ban.In the embodiment shown in Fig. 25, the intersection is recognized based on the coordinates and the current position is tracked. Is to track the location. Therefore, the processing of the current position tracking is the same as that in the above embodiment up to the detection of a bending point, but instead of the processing from the selection of the road to the correction of the distance error performed in the above embodiment, The process of (1) is to perform the process of comparing the approaching direction of the intersection, the bending angle, and the process of correcting the current position.

In the example shown in Fig. 26, when the vehicle enters a circle with a certain radius from the intersection, it is recognized that the vehicle has entered the error range of the intersection. Therefore, if the distance within the error range of the intersection coordinates (x _c , y _c ) is r, the current position (vehicle position) Coordinates (x., Y.) Are

(x _c — χ.) ² + (y _c — y.) ² × r ²

When it reaches a position that satisfies the conditions of, it is assumed that it has entered the circle shown in Fig. 25 (a). Then, as shown in FIG. 4B, the bending is detected, the bending start position and the bending end position are detected, and the azimuths of these positions are set to _20 ° and 100 °, respectively.

 = (Bend end position direction) One (Bend start position direction) = ー 100 °-(One 20 °) =-80 °

, And also detects the bending point position,

D _U p = I curve point positions one bending start position I

I Bend end position / Bend point position I.

In the intersection approach azimuth and bending angle comparison processing, as shown in Fig. 27 (a), the road that enters the intersection signal IV is read out from the road that contains the intersection data and the road that has the same ^ point in the road data, and from these roads determining the orientation of the case which has entered as a direction of the position of the D _UP from intersection position on the node string for the road. The direction is, for example, as shown in FIG.

 ③ 1 50.

 ⑥ 1 1 0 0 °

 ⑦ 6 0 °

⑩ one 25 ° Then, in the example shown in FIG. 26 (b), the road No. も つ having the approach direction closest to the bending start position direction (−20 °) is set as the approach road.

Once the approach roads are found, the roads that come out of intersection Ban No. W and the roads with the same starting point are read from the road data, and the direction change when these roads proceed from approach road ⑩ is found. In this process, the azimuth at the position of D _{down from} the intersection position on the node row of the exit road and the bending start position azimuth on the approach road are obtained as a change. Therefore, when looking at the relationship between approach road ⑩ and each of the outgoing roads ④, ⑤, ⑧, ⑨,

 Becomes Therefore, in the example shown in FIG. 26 (b), since the locus bending angle is 180 °, the road with the closest bending angle to this is determined as the traveling direction.

 FIG. 28 shows the processing routine of the intersection approach direction and the bending angle comparison described above. In the processing routine shown in FIG.

 The process of reading the road that enters the intersection is performed.

In this process, as shown in Fig. 29, the road bank where the end point intersection of the current position road enters is read from the intersection data, and Are set to “Road Ban” and “First Road”, respectively. Then, the loop counter j is set to 0. Next, all the road bans are read out by sequentially reading out the next road number having the same end point from the road data until the next road number having the same end point becomes “the first road sign” while incrementing the loop force counter j. Set the number to “Number of roads to enter”. That is, a process corresponding to the process of reading the road number from the intersection described earlier with reference to FIG. 9 is performed.

 Similarly, the process of reading the road sign coming out of the intersection described in FIG. 9 is performed, and the loop counter j is set to 0. First, the approach road shown in FIG. 27 (b) is determined while incrementing the number of roads into which the loop counter j enters, and the loop counter k is set to 0, and the road exiting the road is set. The bend angle is calculated while incrementing to the number of roads, and the traveling direction road shown in FIG. 27 (c) is determined. Then, the traveling road obtained here is set as a road sign for the current position road.

The current position is corrected after obtaining the road name of the current position road.In this process, the current position coordinates are set as the bending end coordinates on the node train of road 列, as shown in Fig. 30). The current direction is assumed to be the bending end position direction on the node row (—120 °). Then, as shown in FIG. 5B, the end intersection V of Road Signal No. と し て is read from the road data as the next intersection, the intersection coordinates are read from the intersection data, and the vehicle is within the error range of this intersection V. Watch for ingress. FIG. 31 shows the processing routine for the above current position correction. In the processing routine shown in Fig. 31, first, the end point intersection and the node train of the road information of the current position road are read from the road data, and these are respectively read as "the end point intersection of the current position road" and "the node train". "

 In addition, the coordinates of the east longitude and north latitude of “the end point intersection of the current position road” are read from the intersection data, and are set as “the coordinates of the next intersection east longitude and north latitude”.

Then, "Roh one de string" start current position coordinates to Roh one de coordinates on the columns of the distance D _{d own} from (X of [ "previous distance sensor value" + i], Y [ "previous distance sensors Value + i]), and the azimuth between nodes at a distance of D down from the starting point of the “node train” is the azimuth of the current position.

Note that the present invention is not limited to the above-described embodiment, and various modifications are possible. For example, 20 ° used as a rotation angle for determining that an intersection has been turned and 40 ° used as an angle for determining whether there is a corresponding traveling road may be changed according to the determination accuracy or the like. Of course. When the difference ε between the bending angle of the connecting road and the vehicle bending angle is the minimum value (mins) and the value is smaller than 40 °, the road is determined to be the current position road. The road with mi η ε may be determined as the current position road without setting a value. In addition, the current position is tracked, and the distance sensor and the steering angle sensor recognize the current position for each intersection and switch the guidance information. However, using the route search data according to the present invention, Course guidance can be provided without a sensor. That is, even if the sensor cannot be used due to a failure or the like, it can be easily backed up by, for example, a trigger switch. An example is described below.

In FIG. 32, 51 is key input means, 52 is one trigger input means, 53 is guidance data storage means, 54 is guidance information setting means, 55 is display output means, and 56 is audio output means. Is shown. The key input means 51 is composed of numeric keys and function keys, and is used for inputting a code at a predetermined point such as a destination or the present location (guide point). The trigger input means 52 is a touch switch or a push button switch. It consists of a single trigger signal. The guidance data storage means 53 is a memory such as a ROM for storing navigation data and information of each point which is a destination and a current position. The guide information setting means 54 is constituted by, for example, a CPU and performs key input processing, route search, and the like. Information corresponding to each point stored in the guide data storage means 53 is, for example, information for going to a destination by route search. Information and store it in memory such as RAM. Therefore, it includes the main components shown in Fig. 14. The display output means 55 and the voice output means 56 output the guidance information set by the guidance information setting means 54 at the point when the code number of the current location is input by the key input means 51. When a trigger signal is input by the trigger input means 52, for example, the guide information setting means 5 of the next point of the route to the destination according to the order of a, b, c,... Shown in FIG. Set in 4 This is to output the guidance information. For example, when only intersections are targeted as points, the guidance information is information for going to the next intersection at the intersection, which is the guidance point, such as right or left turn. In addition, if there is a second intersection immediately after a turn at the next intersection and there is a second intersection, information on the direction to turn at the first and the lane etc. to be taken at that time may be entered. Of course, may also be included in the information that guides the direction to turn at the second turn. Next, referring to FIG. 34, a description will be given of the flow of processing of the navigation device having means for inputting a code of a destination and a current position, an intersection confirmation trigger, a current position input button, and a guide point as an intersection.

First, when the driver inputs a destination code (step 2), the mode is changed to the route search mode, and information for going to the destination is set for all points other than the destination (step 2). When the route search is completed, the mode is changed to the current location input mode. Here, when the current location code is input (step 3), the traveling direction at that point is output (step 2). Then, when an intersection confirmation trigger is input (start input, step 2), information for going to the destination at the next intersection is output (step 2). Next, it is monitored whether an intersection check trigger is input or a current position input button signal is input (step ⑦). If the intersection check trigger is input, the process returns to step 、 and the current position input button signal is output. If entered, the process returns to step ③. In other words, in this system, If you notice that you have crossed the course to be guided and have traveled to another intersection, the current location input button is pressed. Therefore, every time the trigger is input, the guidance information of the intersection in the route to the destination is output in order, but when the current location input button is pressed, the current location input mode is set. As shown in Fig. 35 (a), when entering the route search mode, the route search process in step 1 first sets a destination in the work area (step 2), and then proceeds from an intersection near the destination. Set the direction (step ⑫). The traveling direction, set the traveling direction d, the previous intersection destination as shown in FIG. (B), then it is possible to repeatedly set the traveling direction d ₂ for the previous intersection. This route search may be performed after the processing in step ③ in FIG. In this case, a route search is performed every time the current location is input. In addition, with the trigger input, guidance information is output according to the route set as a result of the route search, so that the target intersection is limited. Therefore, guidance information for only the intersection may be provided at a minimum.

In the above example, the intersection is set as the guide point. However, if the distance between the intersections is long, special objects such as public facilities in the middle are set as the guide points. You may. As the information for going to the destination, the absolute information characteristic at the point may be used, and a map or a photograph may be output to the display screen and output by voice. This place In such a case, if the output information has a content that draws particular attention, the display mode or display attribute of the portion may be changed, or a different tone or intermittent sound may be used. Furthermore, the guide point may not only be moved forward by a trigger, but also guide information several points ahead of the current position may be appropriately viewed. For example, a combination of the navigation device having the current position calculation method described above and the update method by the above-mentioned touch operation may be used, such as a monotonous road area such as a single road and a complex road area. Good.

 As is clear from the above description, according to the present invention, all the bending angles at the intersection are calculated and corresponded to the bending angle of the vehicle, so that the intersection detection and the selection of the traveling road are performed with high accuracy. be able to. In addition, since the angle based on the running state at the time of bending is detected to detect the bending point position, the bending start point and the bending end point on both sides, accurate current position calculation by distance correction becomes possible, and the distance for each intersection is calculated. The error can be corrected. In addition, the direction of travel to the destination is set for each intersection, and the direction of travel is guided by recognizing the current position at the intersection, so the course to the destination can be freely selected. Guidance can also be provided at intersections.

Also, based on the road network data, the intersection recognition processing is performed on the condition that the vehicle has entered a predetermined range from the end point intersection, the road in the traveling direction is recognized, and the road in the traveling direction is set as the current position road. Output the guidance of the intersection at the end of the course and provide the course guidance repeatedly for each intersection to the destination. It is possible to respond flexibly even from an intersection. Moreover, even if a different road from the guided course is selected as the direction of travel, guidance on the direction of travel to the destination at the end intersection of that road is output, so passing through the intersection without following the optimal course due to road congestion etc. You can still get guidance to your destination. Similarly, even if you get lost on the course, you can run the vehicle appropriately and go to the intersection. If you enter the intersection as the current location, you can immediately track the current position without searching for a route. Further, even if the means for recognizing an intersection becomes unavailable, it can be easily replaced by the driver inputting an intersection recognition signal.

Claims

(1) Search for the route to the destination by inputting the destination, and track the current position while guiding the course to the destination.

5 is a navigation device that has a current position calculation function that performs each of the intersection requests obtained by the route search from the road network information.

 Guidance means that has travel guidance information for each destination and outputs course guidance for the end point intersection of the current position road.

 A road recognizing means for recognizing an outgoing road, and a current position on a road recognized by the road recognizing means for tracking an end point intersection of the road.

 Tracking means that recognizes the traveling direction at the end intersection of the road between the intersections, and outputs the guidance of the next end intersection using the road in the traveling direction as the current position road, so that each destination to the destination A navigation device that is designed to provide repeated course guidance.

 (2) A navigation device that has a current position calculation function that searches for a route to the destination by inputting the destination and tracks the current position while guiding the course to the destination. Intersection data with information on the road and location of at least the end point and 0 starting point for each intersection, road data with information on the starting point intersection and end point, intersection and node row pointers for each road, and the position of the nodes that constitute the road Noichi with information

-A navigation device that is equipped with road sequence data, and is configured to provide course guidance by setting the direction of travel to the destination at each intersection by inputting the destination.

(3) A navigation device that has a current position calculation function that searches for a route to the destination by inputting the destination and tracks the current position while guiding the course to the destination. Road network data with road information between the intersection and the intersection, road recognition means for recognizing the traveling direction road at the intersection, and the current position on the road recognized by the road recognition means is tracked to recognize the end intersection of the road Current position recognition means, and performs intersection recognition processing based on road network data on the condition that the vehicle has entered a predetermined range from the end point intersection, and recognizes the traveling direction road. Napige Shonen

(4) The navigation device according to claim 3, wherein the current position recognizing means is configured to output guidance information on an end point intersection of the road recognized as the traveling direction road.

(5) The navigation device according to claim 4, wherein a traveling direction from the end point intersection to the destination is output as guidance information.

 (6) The navigation device according to claim 3, wherein the current position recognition means is configured to recognize the current position by obtaining a remaining distance to an end point intersection of the road recognized by the road recognition means. .

(7) The navigation device according to claim 3, wherein the current position recognizing means is configured to detect a bend at the intersection and recognize the intersection position of the current position from the bend position.

(8) The napige navigation device according to claim 7, wherein the current position recognizing means is configured to correct the remaining distance to the end point intersection at the current position based on the bending point position at the intersection. apparatus.

 (9) The road recognizing means is configured to recognize the traveling direction road by collating the detection information on the position of the inflection point of the intersection and other inflection points with the inflection information obtained from the road network data. The navigation device according to claim 3.

(10) By inputting a destination, a route search to the destination is performed, and a navigation device having a current position calculation function for performing a course plan to the destination while tracing the current position. Network data with road network information, steering angle detection means, distance detection means, calculation means for calculating both vehicle position and trajectory from steering angle and travel distance, and detecting bending points from steering angle and vehicle direction. A bending point detecting means for calculating a position; a road selecting means for calculating a vehicle bending angle from the bending point position, calculating a bending angle of a connecting road at an intersection from the road network data, and selecting a traveling road; A navigation device that calculates the angle from three points on both sides and calculates the current position from the approach road and intersection information.

 (11) The navigation device according to claim 10, wherein the inflection point detecting means detects the inflection point on condition that the steering angle exceeds a threshold value and exceeds a predetermined rotation angle.

(12) The road selecting means selects a connecting road having the smallest difference between the vehicle bending angle and the connecting road bending angle as a traveling road. 11. The napkination device according to claim 10, wherein:

(13) The navigation device according to (12), wherein a connecting road having a difference between a vehicle bending angle and a connecting road bending angle within a predetermined value range is selected as a traveling road.

 (14) The road selecting means sets the information corresponding to the bending point position and the three points on both sides thereof according to the intersection range distance on condition that the vehicle has passed through the intersection range without detecting the bending point. 13. The navigation device according to claim 12, wherein:

 (15) The navigation device according to (10), further comprising a distance error correcting unit configured to correct a current position of the traveling road by making a bending point position correspond to an intersection position.